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package it.iubar.tkdscore;


 // File   : GUI-lowlevel/animation/analogclock/Clock.java
// Purpose: An analog clock component -- Uses Timer and Calendar.
// Note   : Uses a BufferedImage for clock face so isn't drawn each time.
// Author : Fred Swartz, 1999-2007, Placed in public domain.

import java.util.*;
import java.awt.*;
import java.awt.event.*;
import javax.swing.*;
import java.awt.image.*;

//////////////////////////////////////////////////////////////// Clock class
class Clock extends JComponent {

    //============================================================ constants
    private static final double TWO_PI   = 2.0 * Math.PI;

    private static final int    UPDATE_INTERVAL = 100;  // Millisecs

    //=============================================================== fields
    private Calendar _now = Calendar.getInstance();  // Current time.

    protected int _diameter;                 // Height and width of clock face
    private int _centerX;                  // x coord of middle of clock
    private int _centerY;                  // y coord of middle of clock
    private BufferedImage _clockImage;     // Saved image of the clock face.

    protected javax.swing.Timer _timer;      // Fires to update clock.

    //==================================================== Clock constructor
    public Clock() {
        setPreferredSize(new Dimension(300,300));

        _timer = new javax.swing.Timer(UPDATE_INTERVAL, new ActionListener() {
            public void actionPerformed(ActionEvent e) {
                updateTime();
                repaint();
            }
        });
    }

    //================================================================ start
    /** Start the timer. */
    public void start() {
        _timer.start();
    }

    //================================================================= stop
    /** Stop the timer. */
    public void stop() {
        _timer.stop();
    }

    //=========================================================== updateTime
    protected void updateTime() {
        //... Avoid creating new objects.
        _now.setTimeInMillis(System.currentTimeMillis());
    }

    //======================================================= paintComponent
    @Override public void paintComponent(Graphics g) {
        Graphics2D g2 = (Graphics2D)g;
        g2.setRenderingHint(RenderingHints.KEY_ANTIALIASING,
                            RenderingHints.VALUE_ANTIALIAS_ON);

        //... The panel may have been resized, get current dimensions
        int w = getWidth();
        int h = getHeight();
        _diameter = ((w < h) ? w : h);
        _centerX = _diameter / 2;
        _centerY = _diameter / 2;

        //... Create the clock face background image if this is the first time,
        //    or if the size of the panel has changed
        if (_clockImage == null
                || _clockImage.getWidth() != w
                || _clockImage.getHeight() != h) {
            _clockImage = (BufferedImage)(this.createImage(w, h));

            //... Get a graphics context from this image
            Graphics2D g2a = _clockImage.createGraphics();
            g2a.setRenderingHint(RenderingHints.KEY_ANTIALIASING,
                                 RenderingHints.VALUE_ANTIALIAS_ON);
            drawClockFace(g2a);
        }

        //... Draw the clock face from the precomputed image
        g2.drawImage(_clockImage, null, 0, 0);

        //... Draw the clock hands dynamically each time.
        drawClockHands(g2);
    }

    //====================================== convenience method drawClockHands
    protected void drawClockHands(Graphics2D g2) {

        //... Get the various time elements from the Calendar object.
        int hours   = _now.get(Calendar.HOUR);
        int minutes = _now.get(Calendar.MINUTE);
        int seconds = _now.get(Calendar.SECOND);
        int millis  = _now.get(Calendar.MILLISECOND);

        //... second hand
        int handMin = _diameter / 8;    // Second hand doesn't start in middle.
        int handMax = _diameter / 2;    // Second hand extends to outer rim.
        double fseconds = (seconds + (double)millis/1000) / 60.0;
        drawRadius(g2, fseconds, 0, handMax);

        //... minute hand
        handMin = 0;                    // Minute hand starts in middle.
        handMax = _diameter / 3;
        double fminutes = (minutes + fseconds) / 60.0;
        drawRadius(g2, fminutes, 0, handMax);

        //... hour hand
        handMin = 0;
        handMax = _diameter / 4;
        drawRadius(g2, (hours + fminutes) / 12.0, 0, handMax);
    }

    //======================================= convenience method drawClockFace
    private void drawClockFace(Graphics2D g2) {
        // ... Draw the clock face.  Probably into a buffer.
        g2.setColor(Color.PINK);
        g2.fillOval(0, 0, _diameter, _diameter);
        g2.setColor(Color.BLACK);
        g2.drawOval(0, 0, _diameter, _diameter);

        int radius = _diameter / 2;

        //... Draw the tick marks around the circumference.
        for (int sec = 0; sec < 60; sec++) {
            int tickStart;
            if (sec%5 == 0) {
                tickStart = radius - 10;  // Draw long tick mark every 5.
            } else {
                tickStart = radius - 5;   // Short tick mark.
            }
            drawRadius(g2, sec / 60.0, tickStart , radius);
        }
    }

    //==================================== convenience method drawRadius
    // This draw lines along a radius from the clock face center.
    // By changing the parameters, it can be used to draw tick marks,
    // as well as the hands.
    protected void drawRadius(Graphics2D g2, double percent,
                            int minRadius, int maxRadius) {
        //... percent parameter is the fraction (0.0 - 1.0) of the way
        //    clockwise from 12.   Because the Graphics2D methods use radians
        //    counterclockwise from 3, a little conversion is necessary.
        //    It took a little experimentation to get this right.
        double radians = (0.5 - percent) * TWO_PI;
        double sine   = Math.sin(radians);
        double cosine = Math.cos(radians);

        int dxmin = _centerX + (int)(minRadius * sine);
        int dymin = _centerY + (int)(minRadius * cosine);

        int dxmax = _centerX + (int)(maxRadius * sine);
        int dymax = _centerY + (int)(maxRadius * cosine);
        g2.drawLine(dxmin, dymin, dxmax, dymax);
    }
	
}

